CN107056907B - Application of NAC062D transcription factor protein and coding gene thereof in inhibiting seed germination - Google Patents

Abstract

A NAC062D transcription factor protein is an active form of a membrane-bound transcription factor NAC062 with a transmembrane domain removed, and the amino acid sequence of the protein is sequence 1 in a sequence table, and the nucleotide sequence of the protein is sequence 2 in the sequence table. The coding gene of the NAC062D transcription factor protein is introduced into a transgenic plant cultivation method of a target plant, the coding gene of the NAC062D protein is introduced into the target plant to obtain the transgenic plant; transgenic plant characteristics: 1) there is normally no difference from non-transgenic; 2) after the addition of 10uM inducer beta-estrodal (beta-E), the germination rate of transgenic plants is much lower than that of non-transgenic plants. The transgenic plant inhibits seed germination when the germination rate of the transgenic plant is lower than that of the target plant. The invention provides a transcription factor NAC062D for regulating and controlling plant seed germination and a coding gene thereof, which are introduced into an arabidopsis thaliana Columbia ecotype to obtain a transgenic plant, and the transcription factor is found to be used for regulating and controlling seed germination.

Description

Application of NAC062D transcription factor protein and coding gene thereof in inhibiting seed germination

Technical Field

The invention belongs to the technical field of biology, and particularly relates to an active form NAC062D protein of a membrane-bound transcription factor NAC062 and application of a coding gene thereof in seed germination inhibition.

Background

Researchers of Mensanto company clone and obtain resistance genes (EPsPs genes) from petunia, and introduce the EPsPs genes controlled by 35s promoters in petunia plasmids (caMv) into soybean genomes by applying a particle-mediated transfer deoxyribonucleic acid (DNA) technology, thereby cultivating glyphosate-resistant soybean varieties. The transgenic soybean is approved by the Food and Drug Administration (FDA) in 1994, and is early one of the commercial large-scale popularization production transgenic crops. Because the RR beans have herbicide-tolerant glyphosate genes, the soybeans have high tolerance to the non-selective herbicide, namely, the glyphosate. The application of glyphosate herbicide in the field does not affect the yield of soybean. In addition, there are other types of transgenic soybean, such as high methionine soybean varieties, but the toxicity and safety concerns of transgenic soybean have been controversial, as follows:

1. the transgenosis cannot be reserved, but only fresh transgenosis can be bought, and the transgenosis seeds are only specialized by people for researching transgenosis, so that the trend of interest is not avoided, and the poor idea is inevitably derived once the interest is driven;

2. for example, when soybeans are to be converted into bean sprouts, the transgenes cannot be obtained, and non-transgenes capable of being converted into bean sprouts must be purchased.

Along with the increasing environmental pollution, the greenhouse effect is increased, the surface temperature rises, the temperature changes in four seasons are abnormal, and the haze weather is also changed, so that the growth and development of crops are seriously influenced, and the grain yield is further influenced. Therefore, agricultural research may focus on how to improve the stress resistance of plants under various malignant environmental conditions for a long period of time in the future. Researches show that the arabidopsis thaliana membrane-bound transcription factor plays an important role in regulating and controlling plant growth and development, adversity stress response and the like. NAC membrane-bound transcription factor is one of important transcription factor families in Arabidopsis thaliana, and is a plant-specific transcription factor with multiple biological functions discovered in recent years.

Disclosure of Invention

The invention discloses an active form NAC062D protein of a membrane-bound transcription factor NAC062 and application of a coding gene thereof in inhibiting seed germination.

The purpose and the main technical problem to be solved of the invention are realized by adopting the following technical scheme: a NAC062D transcription factor protein, wherein the full-length NAC062 protein is a membrane-bound transcription factor having a transmembrane domain (TM), and NAC062D is a truncated version thereof without the transmembrane domain, having the amino acid sequence shown as sequence 1 in the sequence listing and the nucleotide sequence shown as sequence 2 in the sequence listing, and being the active form of the membrane-bound transcription factor NAC 062.

The transgenic plant cultivation method provided by the invention is characterized in that a coding gene of NAC062D protein is introduced into a target plant to obtain a transgenic plant; the transgenic plant is characterized in that: 1) there is normally no difference from non-transgenic; 2) after the addition of 10uM inducer beta-estrodal (beta-E), the germination rate of transgenic plants is much lower than that of non-transgenic plants.

In the above method, the plant of interest is a dicotyledonous plant and a monocotyledonous plant.

In the above method, the dicotyledonous plant is arabidopsis thaliana, canola, peanut, cotton, soybean, sunflower, palm tree, olive tree, castor bean, potato, or tobacco; the monocotyledon is rice, corn, wheat, barley, oat, rye, sorghum or lawn grass.

The target plant is arabidopsis thaliana or rape.

In the method, a gene coding for NAC062D protein is introduced into a target plant through a recombinant vector, and the recombinant vector is 1) or 2):

1) identification of transcriptional activation Activity: a vector obtained by inserting the gene encoding the NAC062D protein into PGBK-T7;

2) constructing a transgenic vector: the NAC062D protein coding gene is inserted into a vector obtained by PER 10.

The application of the coding gene of the NAC062D transcription factor protein in inhibiting seed germination, wherein the transgene can inhibit seed germination, and the transgenic plant can inhibit seed germination when the germination rate of the transgenic plant is lower than that of the target plant.

The NAC062D is a truncated version of NAC062 with the transmembrane domain removed, and was transformed into yeast by construction into a PGBK-T7 vector, which was experimentally shown to be transcriptionally active.

Another object of the present invention is to provide a recombinant vector.

The invention provides a recombinant vector which is 1) or 2)

1) Identification of transcriptional activation Activity: the vector is obtained by inserting the coding gene of the NAC062D protein into BamHI and EcoRI of PGBK-T7;

2) constructing a transgenic vector: the NAC062D protein coding gene is inserted into a vector between ASCI and SpeI sites of PER 10.

The invention introduces a transcription factor NAC062D for regulating and controlling plant seed germination and a coding gene thereof into an arabidopsis thaliana Columbia ecotype (Columbia) to obtain a transgenic plant, and finds that the transcription factor can be used for regulating and controlling seed germination. The invention has the following characteristics:

1. the invention adopts an inducible promoter, and when no inducer is added, the plant growth is consistent with the non-transgenic growth, so that the next generation can be propagated;

2. if it is desired to eat seeds such as soybeans, the seeds can be obtained by adding an inducer to inhibit the gene expression and germination of the seeds.

Drawings

FIG. 1 is a gene structural framework diagram of NAC062 and NAC062D. Where black boxes indicate exons, gray boxes indicate 5 'and 3' non-coding regions, and straight lines indicate introns. ATG and TGA represent the start codon and stop codon of the gene, respectively.

FIG. 2 is a schematic representation of the structure of NAC062 and NAC062D proteins. "NAC" represents the NAC domain, with NAC062 having the NAC domain at the N-terminus and the transmembrane domain at the C-terminus for its full length. NAC062D also has a NAC domain at the N-terminus, but the C-terminal transmembrane domain is eliminated.

FIG. 3 is a NAC062D transcriptional activation activity assay.

FIG. 4 shows the expression level identification of PER10-NAC062D transgenic plants; PER10 is transgenic material containing only empty vector as control; NAC062#14, NAC062#16 represent T2 generation transgenic material Nos. 14, 16, respectively, of PER10-NAC062D.

FIG. 5 is a schematic diagram in which: FIG. 5A is a plant number diagram showing the expression level identification of PER10-NAC062D transgenic plants; wt is wild type as control; PER10-NAC062D #6/14/8/25/16, transgenic T2 generation material;

FIG. 5B. plants that germinated entirely without beta-E addition, the transgenes were identical to the control wild type;

FIG. 5C control growth was unaffected 6 days after beta-E addition, whereas PER10-NAC062D seeds did not germinate;

FIG. 5D. after 12 days after beta-E addition, WT growth was consistent, but PER10-NAC062D seeds still did not germinate.

Fig. 6 is a statistical analysis of seed germination rates, with NAC062D transgene suppressing seed germination significantly different.

Detailed Description

The following detailed description will be provided with reference to the accompanying drawings, sequence listing and preferred embodiments for the application of the NAC062D transcription factor protein and its coding gene in inhibiting seed germination, its characteristics and effects.

The test methods used in the implementation are conventional methods unless otherwise specified; the materials, reagents and the like used are commercially available unless otherwise specified.

One, obtaining of a transformed NAC062D yeast strain:

(1) cloning of regulatory genes:

the designed primer sequences for transcriptional activation activity were as follows:

p1 upstream CCGAATTCATGAATCAGAATCTTCATGT

Downstream of P2: AGAGATCTTGCTACAACATCAAAACCAC

Extracting total RNA of wild type arabidopsis thaliana (Columbia ecotype, purchased from American arabidopsis thaliana biological resource center, ABRC) 10-day seedlings by using an RNA extraction kit (Tiangen) in plants and referring to an instruction, synthesizing cDNA by using an invitrogen reverse transcription kit, and carrying out PCR amplification under the guidance of primers P1 and P2; gel electrophoresis was performed to recover a fragment of about 987 bp.

(2) Construction of yeast transformation vector containing NAC 062D:

carrying out 1% running gel electrophoresis detection on the double-enzyme digestion product by using a restriction enzyme ECORI and BAMHI double-enzyme digestion vector PGBK-T7 (purchased from Clonetech company) and a gene NAC062D obtained in experiment 1, and purifying and connecting to obtain a connection product. Transforming Escherichia coli (E.COLI) DH5 alpha competent cells by a heat shock method with a connecting vector, carrying out clone PCR identification, screening positive clones, inoculating the positive clones into a 50mg/L kanamycin-resistant LB liquid culture medium, culturing at 37 ℃ for 16 hours, extracting a plasmid, marking as PGBKNAC062D, and sequencing the plasmid, wherein the sequencing result shows that the gene of a PCR product has a nucleotide sequence of a sequence 2 in a sequence table, is composed of 987 bases, and the coding sequence of the gene is 1-987 bases from the 5' end and codes protein with an amino acid residue sequence of a sequence 1 in the sequence table. Wherein, the 37 th to 492 th bases of the sequence 2 from the 5' end in the sequence table code NAC structural domain and protein interaction structural domain.

(3) Acquisition of NAC 062D-transferred Yeast

Selecting some fresh yeast colonies growing on the plate, inoculating to 5mL YPAD liquid culture medium, and culturing overnight at 30 ℃; inoculating 3mL of overnight-cultured bacterial liquid into a triangular flask containing 50mLYPAD on the next day, and culturing at 30 ℃ for 3-4 hours until the OD600 is optimal to 0.6; centrifuging at room temperature of 700g for 5min, collecting bacterial liquid, re-suspending the bacterial liquid with sterile water, centrifuging at room temperature of 700g for 5min, removing supernatant, adding 1.5mL of 1.1 XTE/LiAc (10mL ═ 1.1mL of 10 XTE +1.1mL of 10 XTAc +7.8mLH2O), re-suspending, transferring to a centrifuge tube of 1.5mL, centrifuging at room temperature of 12000g for 30s, removing supernatant, adding 600 uL of 1.1 XTE/LiAc, re-suspending every 50 uL, and subpackaging into centrifuge tubes to complete yeast competence preparation. Subsequently, yeast transformation is carried out. Firstly, a proper amount of salmon sperm is taken and heated at 95 ℃ for 5min, and then the salmon sperm is quickly inserted into ice to make salmon sperm DNA become single-stranded, thereby helping plasmid DNA to enter a yeast body. Adding 500 mu of LPEG/LiAc (10mLPEG/LiAc is 8mL 50% PEG3350+1mL10 xTE +1mL10 xLiAc), 1-5 mu g of plasmid and 5 mu L (10mg/mL) of denatured salmon sperm into the prepared 100 mu L of yeast competent cells in sequence, mixing uniformly, putting into a 30 ℃ incubator for incubation for 30min, and mixing uniformly once every 10 min; putting the mixture into a water bath kettle at 42 ℃ for hot shock for 15-20 min, and uniformly mixing once every 5 min; centrifugation at 12000g for 15s at room temperature, supernatant removal, sterile water resuspension of yeast, and plating onto corresponding auxotrophic plates. Culturing in 30 deg.C incubator for 2-3 days until yeast colony grows.

(4) NAC 062D-transferred yeast transcription activation activity identification:

to identify whether the truncated form is functional, the inventors have initially performed assays for transcriptional activation activity in yeast. The EMPTY PGBK-T7 vector was used as a control for EMPTY, and the NAC062D vector, in which the NAC062D gene was ligated to the PGBK-T7 vector, was used as an experimental group. And (3) selecting the monoclonal antibody obtained in the step (3), inoculating the monoclonal antibody on a YPDA liquid culture medium, shaking the monoclonal antibody at 30 ℃ overnight, measuring the OD600 of the yeast liquid on the second day, diluting the yeast liquid by using sterile water, and adjusting the OD600 value to be in a similar range. 5 mul of the bacterial liquid is sucked and spotted on an auxotrophic plate culture medium, and the growth condition of the yeast is observed after 3 days. In the soil, it can be seen that NAC062D grew consistently with the control empty vector PGBK-T7 in the absence of TRP tryptophan, that the control did not grow but did grow with NAC062D in the absence of TRP tryptophan and the selection marker HIS histidine in the medium, and that yeast containing NAC062D appeared blue when stained with the other selection marker X-gal, further indicating that this truncated form of NAC062D is transcriptionally active in yeast. As shown in fig. 3.

Second, obtaining of NAC062D transferred Arabidopsis plants:

(1) the primer sequences were designed as follows:

p1 upstream TTGGCGCGCCATGAATCAGAATCTTCATGT

Downstream of P2: GGACTAGTTGCTACAACATCAAAACCACTT

Extracting total RNA of wild type arabidopsis thaliana (Columbia ecotype, purchased from American arabidopsis thaliana biological resource center, ABRC) 10-day seedlings by using an RNA extraction kit (Tiangen) in plants and referring to an instruction, synthesizing cDNA by using an invitrogen reverse transcription kit, and carrying out PCR amplification under the guidance of primers P1 and P2; gel electrophoresis was performed to recover a fragment of about 987 bp.

(2) Construction of a plant inducible expression vector containing NAC 062D:

carrying out 1% running gel electrophoresis detection on the double enzyme digestion product by using a double enzyme digestion vector PER10 of restriction enzyme ASCI and SpeI and a gene NAC062D obtained in experiment 1, and purifying and connecting to obtain a connecting product. PER10 is a plant Expression vector induced by estradiol, specifically referring to the article of Chinese academy genetics and developmental biology, Zuo J, Hare P D, Chua NH. applications of Chemical index Expression Systems in functional genomics and Biotechnology [ M ]// Arabidopsis, protocols. Humana Press, 2006:32942, the ligation vector was transformed with E.coli (E.COLI) DH 5. alpha. competent cells, clone PCR was identified, positive clones were selected, inoculated into 50mg/Lspec spectinomycin-resistant LB liquid medium, cultured at 37 ℃ for 16 hours, extracted, identified by restriction enzymes ASCI and SpeI double digestion for recombinant plasmids, corresponding to the expected result, PER10NAC062D, which was sequenced, which indicated that the gene of the PCR product had the nucleotide sequence of sequence 2 in the sequence list, consisting of 987 bases from the sequence list, and the coding sequence of No. 987-987 bases from the 0625' end, it encodes a protein with an amino acid residue sequence of a sequence 1 in a sequence table. Wherein, the 37 th to 492 th bases of the sequence 2 from the 5' end in the sequence table code NAC structural domain and protein interaction region.

The genome sequence corresponding to the NAC062D gene has a nucleotide sequence of a sequence 3 in a sequence table, and consists of 1639 bases, wherein the first exon of the genome gene is located at the position of 197-374 bases from the 5 ' end, the first intron of the genome gene is located at the position of 375-644 bases from the 5 ' end, the first intron of the genome gene is located at the position of 197-374 bases from the 5 ' end, the second exon of the genome gene is located at the position of 645-925 bases, the second intron of the genome gene is located at the position of 926-1019 bases from the 5 ' end, the third exon of the genome gene is located at the position of 1020-1259 bases from the 5 ' end, the third intron of the genome gene is located at the position of 1260-1351 bases from the 5 ' end, and the fourth exon of the genome gene is located at the position of 1352-1639 bases from the 5 ' end. The gene framework is shown in figure 1, the gene is named NAC062D, and the protein coded by the gene is named NAC062D.

FIG. 2 is a schematic representation of the structure of NAC062 and NAC062D proteins. "NAC" represents the NAC domain, with NAC062 having the NAC domain at the N-terminus and the transmembrane domain at the C-terminus for its full length. NAC062D also has a NAC domain at the N-terminus, but the C-terminal transmembrane domain is eliminated.

(3) NAC062D transformation of Arabidopsis thaliana:

transforming agrobacterium GV3101 competent cells by an electric shock method through a plant expression vector PER10-NAC062D constructed in the step 2, coating the competent cells on an LB resistant plate containing 50mg/L spectinomycin and 50mg/L rifampicin, culturing for 16 hours at 28 ℃ and 150rpm, selecting a single colony of the grown agrobacterium, identifying through PCR of primers P1 and P2, obtaining a 987bp DNA fragment through PCR amplification, indicating the positive recombinant agrobacterium, named as GV3101/PER 10-062D, inoculating GV3101/PER10-NAC062D into LB resistant culture liquid containing 50mg/L spectinomycin and 50mg/L rifampicin, culturing for 20 hours at 28 ℃ and 150rpm, taking 1mL of the strain liquid, inoculating the strain liquid into 300mLLB resistant culture liquid containing 50mg/LL spectinomycin and 50mg/L rifampicin, culturing for 0.6 OD at 28 ℃ and 150rpm, the cells were collected by centrifugation at 5000rpm for 15 minutes, the solution was dissolved in 500mL of MS staining solution containing 5% sucrose, gently shaken, and the wild type Arabidopsis thaliana from which flowers and pods had been removed was poured into a beaker for 10 minutes to obtain T0 generations of PER10-NAC062D plants. The positive T0 generation transformed NAC062D plant is cultured, seeds are harvested, and the obtained seeds are screened by 50mg/L kanamycin to obtain 40T 1 generation transformed NAC062D plants. T2 generation NAC062D plants are obtained through self-crossing, and #6/#14/#8/#25/#16 is selected to carry out RT-PCR detection on the NAC062D expression quantity, which is higher than that of the wild type, thereby indicating that the plants are positive plants.

Thirdly, phenotype identification of NAC 062D-transformed Arabidopsis thaliana:

(1) identification of transgenic PER10-NAC062D plants

T2 seeds of T2 transgenic NAC062D Arabidopsis thaliana (PER10NAC062D) numbered #14 and #16 obtained in step two were first sown on MS medium, and seedlings after 10 days of culture were treated with estrogen MS broth for 10 hours. (+ beta-E) represents the experimental group treated with 10um estrogen (17-beta-ESTRODOIOL, SIGMA, product code E8875) and (-beta-E) represents no reagent treatment as a control. After the treatment, RNA of the whole seedling is extracted, wild arabidopsis thaliana is used as a control, reverse transcription is carried out to obtain Cdna, and the Cdna is used

P3 (upstream primer): 5'-GGGGAAGAAGATTCGAAGTCAG-3'

P4 (downstream primer): 5'-GCTCTGCGGTTGTAGCCTCATC-3' carries out qRT-PCR, detects the expression level of NAC062D gene in the T2 generation transgenic plants, uses wild type Arabidopsis as a control, uses ACTIN as an internal reference, uses ACTIN-F: 5'-GGTAACATTGTGCTCAGTGGTGG-3', ACTIN-R: 5'-AACGACCTTAATCTTCATGCTGC-3' as a primer, the result is shown in figure 4, detects the expression level of NAC062D gene for qRT-PCR technology, and as can be seen from figure 4, compared with wild type Arabidopsis, the expression level of NAC gene in T2 generation PER10-NAC062D transgenic Arabidopsis with numbers of #14 and #16 has different degrees of increase, which indicates that T2 generation PER10-NAC062D transgenic Arabidopsis with numbers of #14 and #16 is positive over-expression Arabidopsis.

(2) Phenotypic analysis of transgenic PER10-NAC062D plants:

seeds of T2 generation PER10-NAC062D Arabidopsis thaliana, selected from #6/#14/#8/#25/#16 numbered as positive as above, were transferred to PER10-NAC062D Arabidopsis thaliana by RT-PCR for NAC062D expression, sown in MS medium containing 10uM estrogen (17-. beta. -ESTRODOCOL, SIGMA, product cat. No. E8875), placed in a light incubator at 22 ℃ for 16 hours, and controlled against wild type Arabidopsis thaliana. Growth of T2 generation NAC062D Arabidopsis and wild type plants was observed after 6 and 12 days, and the results are shown in FIG. 5, where FIG. 5A is a pattern diagram and FIG. 5B is a diagram of plants that were normal when compared to the control wild type without the addition of inducer estrogen (-beta E); FIG. 5C shows that 6 days after the addition of 10uM estrogen inducer (+ beta E) induces NAC062D gene expression, wild type had all germinated, while NAC062D transgenic seeds did not germinate, and FIG. 5D shows that 12 days after the addition of 10uM estrogen inducer (+ beta E) NAC062D seeds did not germinate, while wild type control plant seeds grew normally.

(3) And (5) statistically analyzing the difference. The results according to fig. 5 were statistically determined for the seed germination rates at 6 days and 12 days, respectively, and the results were very significant. As shown in fig. 6.

Fourthly, research on molecular mechanism of NAC062D for regulating seed germination:

seeds of # 14T 2 transgenic NAC062D Arabidopsis thaliana (PER10-NAC062D) obtained in step two were treated in MS medium containing 10uM estrogen (17-. beta. -ESTRODOCOLL, SIGMA, product code E8875) for 12 hours, 24 hours, untreated as a control, seed RNA was extracted and sent to the company for transcriptome sequencing. ABA abscisic acid is a phytohormone with a sesquiterpene structure, and has physiological effects of inducing bud dormancy, leaf abscission, inhibiting cell growth and the like. Researches show that seed germination is closely related to an ABA signal pathway. Transcriptome sequencing results showed that many ABA-associated genes were found to be altered in the transgene, suggesting that NAC062 may inhibit seed germination by modulating gene expression via the ABA pathway, as PER10-NAC062D #14 lists genes associated with the ABA signaling pathway by transcriptome analysis.

A gene which is remarkably different and related to an ABA signal pathway in a transgenic material.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and any simple modification, equivalent change and modification made to the above embodiment according to the technical spirit of the present invention are within the scope of the technical solution of the present invention without departing from the technical solution of the present invention.

Sequence listing

Sequence 1: NAC062D protein sequence 329aa Arabidopsis thaliana (Arabidopsis thaliana)

1 MNQNLHVLSM DSLPVGLRFR PTDEELIRYY LRRKINGHDD DVKAIREIDI

50 CKWEPWDLPD FSVIKTKDSE WLYFCPLDRK YPSGSRQNRA TVAGYWKATG

100 KDRKIKSGKT NIIGVKRTLV FHAGRAPRGT RTNWIIHEYR ATEDDLSGTN

151 PGQSPFVICK LFKKEELVLG EEDSKSDEVE EPAVSSPTVE VTKSEVSEVI

201 KTEDVKRHDI AESSLVISGD SHSDACDEAT TAELVDFKWY PELESLDFTL

251 FSPLHSQVQS ELGSSYNTFQ PGSSNFSGNN NNSFQIQTQY GTNEVDTYIS

301 LDFDSILKSP DEDPEKHKYV LQSGFDVVA

Sequence 2: NAC062D CDS sequence 987bp Arabidopsis thaliana (Arabidopsis thaliana)

1 ATGAATCAGA ATCTTCATGT ATTATCAATG GATTCGTTAC CAGTTGGATT

51 AAGATTCCGT CCAACAGACG AGGAGCTAAT CCGTTACTAT CTCCGTAGGA

101 AAATCAACGG TCACGATGAC GACGTCAAAG CTATCCGTGA GATCGATATT

151 TGCAAATGGG AACCTTGGGA TTTACCTGAT TTTTCTGTGA TCAAAACTAA

201 AGACTCAGAG TGGCTCTACT TCTGTCCATT GGATCGGAAG TATCCGAGTG

251 GAAGTAGACA GAACCGGGCA ACAGTTGCAG GGTACTGGAA AGCCACAGGA

301 AAAGACCGGA AGATAAAATC CGGTAAGACT AACATTATTG GTGTGAAGAG

351 AACTCTAGTT TTCCACGCGG GTAGAGCTCC TAGGGGGACA CGAACCAATT

401 GGATTATTCA TGAGTATCGT GCCACGGAGG ATGATCTTAG TGGTACCAAT

451 CCTGGCCAGA GTCCGTTTGT TATATGCAAA TTGTTCAAGA AAGAAGAACT

501 GGTTTTAGGG GAAGAAGATT CGAAGTCAGA TGAAGTTGAA GAACCTGCTG

551 TCTCGTCTCC AACTGTCGAA GTGACTAAGT CAGAAGTATC TGAGGTAATT

601 AAAACAGAAG ACGTGAAGCG TCATGACATA GCAGAATCTT CTCTTGTAAT

651 CTCTGGAGAT TCTCATAGTG ATGCTTGTGA TGAGGCTACA ACCGCAGAGC

701 TTGTAGATTT TAAATGGTAT CCGGAATTGG AGTCCTTAGA TTTCACGCTG

751 TTCTCTCCAT TACACTCTCA AGTCCAATCT GAGCTTGGAT CCTCTTACAA

801 CACATTCCAG CCTGGCTCGA GTAATTTTTC AGGGAACAAC AACAACAGCT

851 TCCAAATCCA GACTCAGTAT GGTACAAATG AAGTAGATAC GTATATATCT

901 GATTTTCTTG ATTCGATTCT CAAGAGCCCA GACGAGGATC CAGAGAAGCA

951 CAAGTATGTT TTGCAAAGTG GTTTTGATGT TGTAGCA

Sequence 3 NAC062D genome sequence 1639bp Arabidopsis (Arabidopsis thaliana)

1 ACATCTGCCT TCTTCTTCAC TTTACCAAAA TCATCGAATC CATTTTTAGG

51 GTTTTTGTTT TCTCTCTAAA TTTTTATTGT TATCTTCTTC GCGATACCTT

101 GGAATCGCAT CTCTGAGATA GATAAATAAT TCTGATTCGT ATCTTTAAAT

151 CTTGGGTTCT TCTTCTTCTC GCGATTCGTT TAAAAGAGCA GCATCAATGA

201 ATCAGAATCT TCATGTATTA TCAATGGATT CGTTACCAGT TGGATTAAGA

251 TTCCGTCCAA CAGACGAGGA GCTAATCCGT TACTATCTCC GTAGGAAAAT

301 CAACGGTCAC GATGACGACG TCAAAGCTAT CCGTGAGATC GATATTTGCA

351 AATGGGAACC TTGGGATTTA CCTGGTACTT ACTTACTTAC TTCTTCATCT

401 CTTTATTCAT AAATTTACAC TTTTTCTATA GATCCTCTTT GATTTCTCTG

451 GCATTATGTT GAATTGAGAA ATGGTAGAAC TTAAAATTTG TAGCTTTAGT

501 TTCTATGGTG AAGAAAGTTA ATAACTTTAA ACCGATCATA TGTGTTTGAT

551 ATAGTTTAGT TTTGGGTATG TGGTTATATC TCTGTTAAGG TGTAGTGTAA

601 GTGACTGAAA TTTGATTAAA AGATGTGATT TTTTTTTGTT GTAGATTTTT

651 CTGTGATCAA AACTAAAGAC TCAGAGTGGC TCTACTTCTG TCCATTGGAT

701 CGGAAGTATC CGAGTGGAAG TAGACAGAAC CGGGCAACAG TTGCAGGGTA

751 CTGGAAAGCC ACAGGAAAAG ACCGGAAGAT AAAATCCGGT AAGACTAACA

801 TTATTGGTGT GAAGAGAACT CTAGTTTTCC ACGCGGGTAG AGCTCCTAGG

851 GGGACACGAA CCAATTGGAT TATTCATGAG TATCGTGCCA CGGAGGATGA

901 TCTTAGTGGT ACCAATCCTG GCCAGGTAAA TAATGCATAC TTTTAGATGT

951 GTAACCATTG GAAAACTAAA TTTGGCTCTG TAGCTTATTG TGTGCTTGTG

1001 TTGATATATA TATATGCAGA GTCCGTTTGT TATATGCAAA TTGTTCAAGA

1051 AAGAAGAACT GGTTTTAGGG GAAGAAGATT CGAAGTCAGA TGAAGTTGAA

1101 GAACCTGCTG TCTCGTCTCC AACTGTCGAA GTGACTAAGT CAGAAGTATC

1151 TGAGGTAATT AAAACAGAAG ACGTGAAGCG TCATGACATA GCAGAATCTT

1201 CTCTTGTAAT CTCTGGAGAT TCTCATAGTG ATGCTTGTGA TGAGGCTACA

1251 ACCGCAGAGG TGAGGACATT GAAAAATTCT CTTAGACAGT TTTTAGATGA

1301 TTGTCTCTAG TGTCTGTTTG AATACTAATG ATGTTTATTT TCGGCATGCA

1351 GCTTGTAGAT TTTAAATGGT ATCCGGAATT GGAGTCCTTA GATTTCACGC

1401 TGTTCTCTCC ATTACACTCT CAAGTCCAAT CTGAGCTTGG ATCCTCTTAC

1451 AACACATTCC AGCCTGGCTC GAGTAATTTT TCAGGGAACA ACAACAACAG

1501 CTTCCAAATC CAGACTCAGT ATGGTACAAA TGAAGTAGAT ACGTATATAT

1551 CTGATTTTCT TGATTCGATT CTCAAGAGCC CAGACGAGGA TCCAGAGAAG

1601 CACAAGTATG TTTTGCAAAG TGGTTTTGAT GTTGTAGCA

Claims (3)

1. A transgenic arabidopsis cultivation method for introducing coding genes of NAC062D transcription factor protein into arabidopsis, which is characterized in that: introducing a coding gene of NAC062D protein into arabidopsis thaliana by using an estradiol induction expression vector to obtain transgenic arabidopsis thaliana; the transgenic arabidopsis thaliana is characterized in that: 1) there is no difference from non-transgenic Arabidopsis under normal conditions; 2) after 10 mu mol/L inducer beta-estradiol is added, the germination rate of the transgenic arabidopsis is far lower than that of the non-transgenic arabidopsis;

   NAC062D is an active form of a membrane-bound transcription factor NAC062 with a transmembrane domain TM removed, and has an amino acid sequence of sequence 1 and a nucleotide sequence of sequence 2 in the sequence table.
2. 2. The method of claim 1, wherein: the estradiol inducible expression vector is PER 10.
3. 3. The use of a gene encoding NAC062D transcription factor protein, according to claim 1, for inhibiting arabidopsis thaliana seed germination, wherein: the over-expression of NAC062D can inhibit the germination of Arabidopsis seeds, and the germination rate of Arabidopsis with over-expression of NAC062D is lower than that of wild Arabidopsis.

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